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United States Patent |
6,057,238
|
Raina
,   et al.
|
May 2, 2000
|
Method of using hydrogen and oxygen gas in sputter deposition of
aluminum-containing films and aluminum-containing films derived
therefrom
Abstract
An aluminum-containing film having an oxygen content within the film. The
aluminum-containing film is formed by introducing hydrogen gas and oxygen
gas along with argon gas into a sputter deposition vacuum chamber during
the sputter deposition of aluminum or aluminum alloys onto a semiconductor
substrate. The aluminum-containing film so formed is hillock-free and has
low resistivity, relatively low roughness compared to pure aluminum, good
mechanical strength, and low residual stress.
Inventors:
|
Raina; Kanwal K. (Boise, ID);
Wells; David H. (Boise, ID)
|
Assignee:
|
Micron Technology, Inc. (Boise, ID)
|
Appl. No.:
|
045272 |
Filed:
|
March 20, 1998 |
Current U.S. Class: |
438/688; 257/E21.169; 438/927; 438/937 |
Intern'l Class: |
H01L 021/476.3 |
Field of Search: |
438/688,927,937
|
References Cited
U.S. Patent Documents
3631304 | Dec., 1971 | Bhatt | 204/192.
|
3654526 | Apr., 1972 | Cunningham et al. | 257/59.
|
3717564 | Feb., 1973 | Bhatt | 317/234.
|
4845050 | Jul., 1989 | Kim | 437/192.
|
4871647 | Oct., 1989 | Kim et al. | 257/357.
|
5096279 | Mar., 1992 | Hornbeck et al. | 359/230.
|
5148259 | Sep., 1992 | Kato et al. | 357/67.
|
5328873 | Jul., 1994 | Mikoshiba et al. | 437/187.
|
5358901 | Oct., 1994 | Fiordalice et al. | 437/192.
|
5367179 | Nov., 1994 | Mori et al. | 257/59.
|
5387546 | Feb., 1995 | Maeda | 437/174.
|
5393699 | Feb., 1995 | Mikoshiba et al. | 437/187.
|
5403762 | Apr., 1995 | Takemura | 437/40.
|
5416351 | May., 1995 | Ito et al. | 430/21.
|
5434104 | Jul., 1995 | Cain et al. | 437/198.
|
5449640 | Sep., 1995 | Hunt et al. | 437/190.
|
5453405 | Sep., 1995 | Fan et al. | 437/228.
|
5475267 | Dec., 1995 | Ishii et al. | 257/752.
|
5486939 | Jan., 1996 | Fulks | 359/74.
|
5491347 | Feb., 1996 | Allen et al. | 257/59.
|
5518805 | May., 1996 | Ho et al. | 428/213.
|
5572046 | Nov., 1996 | Takemura | 257/66.
|
5580468 | Dec., 1996 | Fujikawa et al. | 216/27.
|
5583075 | Dec., 1996 | Ohzu et al. | 437/203.
|
5594280 | Jan., 1997 | Sekiguchi et al. | 257/771.
|
5739549 | Apr., 1998 | Takemura et al. | 317/234.
|
Other References
# Onishi, "Influence of adding transition metal elements to an aluminum
target on electrical resistivity and hillock resistance in
sputter-deposited aluminum alloy thin films," J. Vac. Sci. Technol. A,
vol. 14, No. 5, pp. 2728-2735 (Sep./Oct. 1996).
# Kim et al., "Pure AI an AI-Alloy Gate-Line Processes in TFT-LCDs," SID 96
Digest, .sctn. 22.2, pp. 337-340 (1996).
# Hu et al., "Electromigration and stress-induced voiding in fine AI and
AI-alloy thin film lines," IBM J. Res. Develop., vol. 39, No. 4, pp.
465-497 (Jul. 1995).
# Ryan et al., "The evolution of interconnection technology at IBM," IBM J.
Res. Develop., vol. 39, No. 4, pp. 465-497 (Jul. 1995).
# Lee et al., Effect of hydrogen addition on the preferred orientation of
AIN films prepared by reactive sputtering, Thin Solid Films, vol. 271, pp.
50-55 (Jul. 1995).
# Hall et al., "A Clad Almuminum Gate Process for Advanced TFT
Manufacturing," Applied Komatsu Technology, pp. 93-94 (1992).
# Koubuchi et al., "Stress migration resistance and contact
characterization of Al-Pd-Si interconnects for very large scale
integrations," J. Vac. Technol. B, vol. 8, No. 6, pp. 1232-1238 (Nov./Dec.
1990).
# Iwamura et al., "Characterization of Al-Nd Alloy Thin Films for
Interconnections of TFT-LCDs," Elect. Resl. Lab., (1995).
# Rohde et al., Sputter Deposition of Thin Films, pp. 94-126 (date unknown)
.
|
Primary Examiner: Niebling; John F.
Assistant Examiner: Ghuka; Alexander G.
Attorney, Agent or Firm: Trask, Britt & Rossa
Claims
What is claimed is:
1. A method of forming a substantially hillock-free aluminum-containing
film comprising:
placing a substrate in a vacuum deposition chamber, said vacuum deposition
chamber including an aluminum-containing target therein;
evacuating said vacuum deposition chamber;
applying an electrical field between said aluminum-containing target and
said substrate; and
introducing argon gas, hydrogen gas, and oxygen gas into said vacuum
deposition chamber.
2. The method of claim 1, further including maintaining said vacuum
deposition chamber at a pressure between about 0.5 and 2.5 millitorr.
3. The method of claim 1, wherein said argon gas is introduced into said
vacuum deposition chamber at a rate of between about 25 and 90 standard
cubic centimeters per minute.
4. The method of claim 1, wherein said hydrogen gas is introduced into said
vacuum deposition chamber at a rate of between about 50 and 400 standard
cubic centimeters per minute.
5. The method of claim 1, wherein said oxygen gas is introduced into said
vacuum deposition chamber at a rate of between about 0.25 and 2 standard
cubic centimeters per minute.
6. The method of claim 1, wherein a ratio of argon gas to hydrogen gas is
preferably between about 1:1 and 1:6.
7. The method of claim 1, wherein applying said electrical field between
said aluminum-containing target and said substrate comprises applying
direct current power of one polarity to said aluminum-containing target
and of an opposing polarity to said substrate.
8. The method of claim 7, wherein said direct current power is between
about 1 and 4 kilowatts.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates generally to a method of sputter deposition of an
aluminum-containing film onto a semiconductor substrate, such as a silicon
wafer. More particularly, the invention relates to using hydrogen and
oxygen gas with argon during the deposition of aluminum or aluminum alloys
to form an aluminum-containing film which is resistant to hillock
formation.
2. State of the Art
Thin film structures are becoming prominent in the circuitry components
used in integrated circuits ("ICs") and in active matrix liquid crystal
displays ("AMLCDs"). In many applications utilizing thin film structures,
low resistivity of metal lines (gate lines and data lines) within those
structures is important for high performance. For example with AMLCDs, low
resistivity metal lines minimize RC delay which results in faster screen
refresh rates. Refractory metals, such as chromium (Cr), molybdenum (Mo),
tantalum (Ta), and tungsten (W), have resistances which are too high for
use in high performance AMLCDs or ICs. Additionally, the cost of
refractory metals is greater than non-refractory metals. From the
standpoint of low resistance and cost, aluminum (Al) is a desirable metal.
Furthermore, aluminum is advantageous because it forms an oxidized film on
its outer surfaces which protects the aluminum from environmental attack,
and aluminum has good adhesion to silicon and silicon compounds.
An aluminum film is usually applied to a semiconductor substrate using
sputter deposition. Sputter deposition is generally performed inside the
vacuum chamber where a solid slab (called the "target") of the desired
film material, such as aluminum, is mounted and a substrate is located.
Argon gas is introduced into the vacuum chamber and an electrical field is
applied between the target and the substrate which strikes a plasma. In
the plasma, gases are ionized and accelerated, according to their charge
and the applied electrical field, toward the target. As the argon atoms
accelerate toward the target, they gain sufficient momentum to knock off
or "sputter" atoms and/or molecules from the target's surface upon impact
with the target. After sputtering the atoms and/or molecules from the
target, the argon ions, the sputtered atoms/molecules, argon atoms and
electrons generated by the sputtering process, form a plasma region in
front of the target before coming to rest on the semiconductor substrate,
which is usually positioned below or parallel to the target within the
vacuum chamber. However, the sputtered atoms and/or molecules may scatter
within the vacuum chamber without contributing to the establishment of the
plasma region and thus not deposit on the semiconductor substrate. This
problem is at least partly resolved with a "magnetron sputtering system"
which utilizes magnets behind and around the target. These magnets help
confine the sputtered material in the plasma region. The magnetron
sputtering system also has the advantage of needing lower pressures in the
vacuum chamber than other sputtering systems. Lower pressure within the
vacuum chamber contributes to a cleaner deposited film. The magnetron
sputtering system also results in a lower target temperature, which is
conducive to sputtering of low melt temperature materials, such as
aluminum and aluminum alloys.
Although aluminum films have great advantages for use in thin film
structures, aluminum has an unfortunate tendency to form defects, called
"hillocks". Hillocks are projections that erupt in response to a state of
compressive stress in a metal film and consequently protrude from the
metal film surface.
There are two reasons why hillocks are an especially severe problem in
aluminum thin films. First, the coefficient of thermal expansion of
aluminum (approximately 23.5.times.10.sup.-6 /.degree.C.) is almost ten
times as large as that of a typical silicon semiconductor substrate
(approximately 2.5.times.10.sup.-6 /.degree.C.). When the semiconductor
substrate is heated during different stages of processing of a
semiconductor device, the thin aluminum film, which is strongly adhered to
the semiconductor substrate, attempts to expand more than is allowed by
the expansion of the semiconductor substrate. The inability of the
aluminum film to expand results in the formation of the hillocks to
relieve the expansion stresses. The second factor involves the low melting
point of aluminum (approximately 660.degree. C.), and the consequent high
rate of vacancy diffusion in aluminum films. Hillock growth takes place as
a result of a vacancy-diffusion mechanism. Vacancy diffusion occurs as a
result of the vacancy-concentration gradient arising from the expansion
stresses. Additionally, the rate of diffusion of the aluminum increases
very rapidly with increasing temperature. Thus, hillock growth can thus be
described as a mechanism that relieves the compressive stress in the
aluminum film through the process of vacancy diffusion away from the
hillock site, both through the aluminum grains and along grain boundaries.
This mechanism often drives up resistance and may cause open circuits.
The most significant hillock-related problem in thin film structure
manufacturing occurs in multilevel thin film structures. In such
structures, hillocks cause interlevel shorting when they penetrate or
punch through a dielectric layer separating overlying metal lines. This
interlevel shorting can result in a failure of the IC or the AMLCD. Such a
shorted structure is illustrated in FIG. 11.
FIG. 11 illustrates a hillock 202 in a thin film structure 200. The thin
film structure 200 comprises a semiconductor substrate 204, such as a
silicon wafer, with a patterned aluminum layer 206 thereon. A lower
dielectric layer 208, such as a layer of silicon dioxide or silicon
nitride, is deposited over the semiconductor substrate 204 and the
patterned aluminum layer 206. The lower dielectric layer 208 acts as an
insulative layer between the patterned aluminum layer 206 and an active
layer 210 deposited over the lower dielectric layer 208. A metal line 212
is patterned on the active layer 210 and an upper dielectric layer 214 is
deposited over the metal line 212 and the active layer 210. The hillock
202 is shown penetrating through the lower dielectric layer 208 and the
active layer 210 to short with the metal line 212.
Numerous techniques have been tried to alleviate the problem of hillock
formation, including: adding elements, such as tantalum, cobalt, nickel,
or the like, that have a limited solubility in aluminum (however, this
generally only reduces but not eliminates hillock formation); depositing a
layer of tungsten or titanium on top or below the aluminum film (however,
this requires additional processing steps); layering the aluminum films
with one or more titanium layers (however, this increases the resistivity
of the film); and using hillock resistant refractory metal films such as
tungsten or molybdenum, rather than aluminum (however, as previously
mentioned, these refractory metals are not cost effective and have
excessive resistivities for use in high performance ICs and AMLCDs).
In particular with AMLCDs, and more particularly with thin film
transistor-liquid crystal displays ("TFT-LCDs"), consumer demand is
requiring larger screens, higher resolution, and higher contrast. As
TFT-LCDs are developed in response to these consumer demands, the need for
metal lines which have low resistivity and high resistance to hillock
formation becomes critical.
Therefore, it would be advantageous to develop an aluminum-containing
material which is resistant to the formation of hillocks and a technique
for forming an aluminum-containing film on a semiconductor substrate which
is substantially free from hillocks, while using inexpensive,
commercially-available, widely-practiced semiconductor device fabrication
techniques and apparatus without requiring complex processing steps.
SUMMARY OF THE INVENTION
The present invention relates to a method of introducing hydrogen and
oxygen gas along with argon gas into a sputter deposition vacuum chamber
during the sputter deposition of aluminum or aluminum alloys onto a
semiconductor substrate, including but not limited to glass, quartz,
aluminum oxide, silicon, oxides, plastics, or the like, and to the
aluminum-containing films resulting therefrom.
The method of the present invention involves using a standard sputter
deposition chamber, preferably a magnetron sputter deposition chamber, at
a power level of between about 1 and 4 kilowatts (KW) of direct current
power applied between a cathode (in this case the aluminum target) and an
anode (flat panel display substrate--i.e., soda lime glass) to create the
plasma (after vacuum evacuation of the chamber). The chamber is maintained
at a pressure of between about 0.5 and 2.5 millitorr with an appropriate
amount of argon gas, hydrogen gas, and oxygen gas flowing into the
chamber. The argon gas is preferably fed at a rate between about 25 and 90
standard cubic centimeters per minute ("sccm"). The hydrogen gas is
preferably fed at a rate between about 50 and 400 sccm. The oxygen gas is
preferably fed at a rate between about 0.25 and 2 sccm (preferably in an
atmospheric air stream). The ratio of argon gas to hydrogen gas is
preferably between about 1:1 and about 1:6. The films with higher
hydrogen/argon ratios exhibited smoother texture than lower hydrogen/argon
ratios. The deposition process is conducted at room temperature (i.e.,
about 22.degree. C.).
The aluminum-containing films resulting from this method have an average
oxygen content between about 12 and 30% (atomic) oxygen in the form of
aluminum oxide (Al.sub.2 O.sub.3) with the remainder being aluminum. The
aluminum-containing films exhibit golden-yellow color when formed under
the process parameters described. The most compelling attribute of the
aluminum-containing films resulting from this method is that they are
hillock-free, even after being subjected to thermal stresses.
Although the precise mechanical and/or chemical mechanism for forming these
aluminum-containing films is not completely understood, it appears that
the hydrogen gas functions in the manner of a catalyst for delivering
oxygen into the aluminum-containing films. Although the flow of the oxygen
gas into the vacuum chamber is small compared to the flow of argon gas and
hydrogen gas, there is a relatively large percentage of oxygen present in
the deposited aluminum-containing films. In experiments by the inventors,
oxygen gas was introduced into the vacuum chamber, without any hydrogen
gas being introduced (i.e., only oxygen gas and argon gas introduced). The
resulting films deposited on the substrate did not have a measurable
amount (by x-ray photoelectron spectroscopy) of oxygen present.
As stated previously, oxygen is present in the deposited
aluminum-containing film in the form of aluminum oxide. However, aluminum
oxide is an insulator. It is counter-intuitive to form an insulative
compound (which should increase the resistivity of the film) in a film
which requires very low resistivity. However, it has been found that the
formation of the aluminum oxide does not interrupt the conducting matrix
of aluminum grains within the aluminum-containing film. Thus, the
resistivity of the aluminum-containing film is surprisingly low, in the
order of between about 6 and 10 micro ohm-cm. This is particularly
striding in light of the fact that aluminum oxide is present in the range
of between about 12 and 30% (atomic). The grain size of these
aluminum-containing films is between about 400 and 600 angstroms (.ANG.).
Aside from being substantially hillock-free and having a low resistivity
(i.e., high conductivity), the resultant aluminum-containing films have
additional desirable properties including low roughness, low residual
stress, and good mechanical strength (as determined by a simple scratch
test compared to pure aluminum or by the low compressive stress (between
about -5.times.10.sup.8 and -1.times.10.sup.9 dyne/cm.sup.2), which is
considered to be an indication of high scratch resistance). Measurements
of the aluminum-containing films have shown that the roughness before and
after annealing is low compared to pure aluminum (about 600-1000 .ANG.
before annealing and 400-550 .ANG. after annealing). Low roughness
prevents stress migration, prevents stress-induced voids, and,
consequently, prevents hillock formation. Additionally, low roughness
allows for better contact to other thin films and widens the latitude of
subsequent processing steps, since less rough films result in less
translation of crests and valleys in the film layers deposited thereover,
less diffuse reflectivity which makes photolithography easier, no need to
clad the aluminum in the production of AMLCDs (rough aluminum traps charge
which effects electronic performance [i.e., high or variable
capacitance]), and more uniform etching.
The mechanical strength of the aluminum-containing films resulting from the
process of the invention is higher than conventionally sputtered thin
films of aluminum and some of its alloys. A high mechanical strength
results in the resulting aluminum-containing films being resistant to both
electromigration and stress induced voiding.
This combination of such properties is superior to that of thin films of
aluminum and its alloys which are presently known. These properties make
the aluminum-containing films of the present invention desirable for
electronic device interconnects. These properties are also desirable in
thin films for optics, electro-optics, protective coatings, and ornamental
applications.
BRIEF DESCRIPTION OF THE DRAWINGS
While the specification concludes with claims particularly pointing out and
distinctly claiming that which is regarded as the present invention, the
advantages of this invention can be more readily ascertained from the
following description of the invention when read in conjunction with the
accompanying drawings in which:
FIGS. 1 and 2 are illustrations of scanning electron micrographs of an
aluminum thin film produced by a prior art method before annealing and
after annealing, respectively;
FIGS. 3 and 4 are illustrations of scanning electron micrographs of an
aluminum thin film (Test Sample 1) produced by a method of the present
invention before annealing and after annealing, respectively;
FIGS. 5 and 6 are illustrations of scanning electron micrographs of an
aluminum thin film (Test Sample 2) produced by a method of the present
invention before annealing and after annealing, respectively;
FIG. 7 is an x-ray photoelectron spectroscopy graph showing the oxygen
content through the depth of an aluminum-containing film produced by a
method of the present invention;
FIG. 8 is a graph of roughness measurements (by atomic force microscopy) of
various aluminum-containing films made in accordance with methods of the
present invention;
FIG. 9 is a cross-sectional side view illustration of a thin film
transistor utilizing a gate electrode and source/drain electrodes formed
from an aluminum-containing film produced by a method of the present
invention;
FIG. 10 is a schematic of a standard active matrix liquid crystal display
layout utilizing column buses and row buses formed from an
aluminum-containing film produced by a method of the present invention;
and
FIG. 11 is a cross-sectional side view illustration of interlevel shorting
resulting from hillock formation.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
The method of the present invention preferably involves using a
conventional magnetron sputter deposition chamber within the following
process parameters:
______________________________________
Power (DC): between about 1 and 4 KW
Pressure: between about 0.5 and 2.5 millitorr
Argon Gas Flow Rate: between about 25 and 90 sccm
Hydrogen Gas Flow Rate: between about 50 and 400 sccm
Oxygen Gas Flow Rate: between about 0.25 and 2 sccm
Argon:Hydrogen Gas Ratio: between about 1:1 and 1:6
______________________________________
The operation of the magnetron sputter deposition chamber generally
involves applying the direct current power between the cathode (in this
case the aluminum target) and the anode (substrate) to create the plasma.
The chamber is maintained within the above pressure range and an
appropriate mixture of argon gas, hydrogen gas, and oxygen gas is
delivered to the chamber. The aluminum-containing films resulting from
this method have between about 12 and 30% (atomic) oxygen in the form of
aluminum oxide (Al.sub.2 O.sub.3) with the remainder being aluminum.
It is believed that the primary hillock prevention mechanism is the
presence of the hydrogen in the system, since it has been found that even
using the system with no oxygen or virtually no oxygen present (trace
amounts that are unmeasurable by present equipment and techniques) results
in a hillock-free aluminum-containing film. It is also believed that the
presence of oxygen in the film is primarily responsible for a smooth (less
rough) aluminum-containing film, since roughness generally decreases with
an increase in oxygen content in the film.
EXAMPLE 1
A control sample of an aluminum film coating on a semiconductor substrate
was formed in a manner exemplary of prior art processes (i.e., no hydrogen
gas present) using a Kurdex-DC sputtering system to deposit aluminum from
an aluminum target onto a soda-lime glass substrate.
The substrate was loaded in a load lock chamber of the sputtering system
and evacuated to about 5.times.10.sup.-3 torr. The load lock was opened
and a main deposition chamber was evacuated to about 10.sup.-7 torr before
the substrate was moved into the main deposition chamber for the
sputtering process. The evacuation was throttled and specific gases were
delivered into the main deposition chamber. In the control deposition,
argon gas alone was used for sputtering process. Once a predetermined
amount of argon gas stabilized (about 5 minutes) in the main deposition
chamber, about 2 kilowatts of direct current power was applied between a
cathode (in this case the aluminum target) and the anode (substrate) to
create the plasma, as discussed above. The substrate was moved in front of
the plasma from between about 8 and 10 minutes to form an
aluminum-containing film having a thickness of about 1800 angstroms.
Table 1 discloses the operating parameters of the sputtering equipment and
the characteristics of the aluminum film formed by this process.
TABLE 1
______________________________________
Sputtering Process Parameters
Control Sample
______________________________________
Power (KW) 2
Pressure (mtorr) 2.05
Gas Flow (sccm) Argon = 90
Characterization Parameters and Properties
Thickness (.ANG.) 1800
Stress (dyne/cm.sup.2) (compressive) -4.94 .times. 10.sup.8 (C)
Roughness (.ANG.) 1480 (unannealed)
2040 (annealed)
Resistivity (.mu..OMEGA.-cm) 2.70
Grain Size (.ANG.) 1000-1200
Hillock Density approx. 2 to 5 .times. 10.sup.9 /m.sup.2
______________________________________
The measurements for the characterization parameters and properties were
taken as follows: thickness--Stylus Profilometer and scanning electron
microscopy; stress--Tencor FLX using laser scanning; roughness--atomic
force microscopy; resistivity--two point probe; grain size--scanning
electron microscopy; and hillock density--scanning electron microscopy.
FIG. 1 is an illustration of a scanning electron micrograph of the surface
of the aluminum film produced under the process parameters before
annealing. FIG. 2 is an illustration of a scanning electron micrograph of
the surface of the aluminum-containing film produced under the process
parameters after annealing. Both FIGS. 1 and 2 show substantial hillock
formation both before and after annealing.
EXAMPLE 2
Two test samples (test sample 1 and test sample 2) of an aluminum film
coating on a semiconductor substrate were fabricated using the method of
the present invention. These two test samples were also formed using the
Kurdex-DC sputtering system with an aluminum target depositing on a
soda-lime glass substrate.
The operating procedures of the sputtering system were essentially the same
as the control sample, as discussed above, with the exception that the gas
content vented into the main deposition chamber included argon, hydrogen,
and oxygen (wherein oxygen is preferably introduced in an atmospheric air
stream). Additionally, the pressure in the main deposition chamber during
the deposition and the thickness of the aluminum-containing film were
varied from that control sample for each of the test samples.
Table 2 discloses the operating parameters of the sputtering equipment and
the characteristics of the two aluminum films formed by the process of the
present invention.
TABLE 2
______________________________________
Sputtering Process Parameters
Test Sample 1
Test Sample 2
______________________________________
Power (KW) 2 2
Pressure (mtorr) 0.66 2.5
Gas Flow (sccm) Argon = 25 Argon = 90
Hydrogen = 50 Hydrogen = 200
Oxygen Flow (sccm) about 0.25 to 0.5 about 0.25 to 0.5
Characterization Parameters
and Properties
Thickness (.ANG.) 2000 1800
Stress (dyne/cm.sup.2) 4.93 .times. 10.sup.8 (T)* -1.6 .times. 10.sup.8
(C)**
Roughness (.ANG.) 980 (unannealed) 640 (unannealed)
520 (annealed) 410 (annealed)
Resistivity (.mu..OMEGA.-cm) 6.4 7.2
Grain Size (.ANG.) 400-600 400-600
Film Oxygen Content approx. max. 25% approx. max. 20%
Hillock Density no hillocks present no hillocks present
______________________________________
*Tensile
**Compressive
FIG. 3 is an illustration of a scanning electron micrograph of the surface
of the Test Sample 1 before annealing. FIG. 4 is an illustration of a
scanning electron micrograph of the surface of the Test Sample 1 after
annealing. FIG. 5 is an illustration of a scanning electron micrograph of
the surface of the Test Sample 2 before annealing. FIG. 6 is an
illustration of a scanning electron micrograph of the surface of the Test
Sample 2 after annealing. As it can be seen from FIGS. 3-6, no hillocks
form on either sample whether annealed or not.
EXAMPLE 3
A number of aluminum-containing films were made at different ratios of
Ar/H.sub.2 and various system pressures were measured for oxygen content
within the films. The oxygen gas flow rate was held constant at about 2
sccm and the power was held constant at 2 KW. The oxygen content was
measure by XPS (x-ray photoelectron spectroscopy). The results of the
measurements are shown in Table 3.
TABLE 3
______________________________________
Sample Ar/H.sub.2 Pressure
Oxygen Content
Number (sccm) Ar/H.sub.2 Ratio (millitorr) Range (atomic %)
______________________________________
1 90/400 0.225 2.50 12-25
2 90/300 0.300 2.40 15-30
3 50/200 0.250 1.50 15-25
4 25/50 0.500 0.60 25-30
5 90/50 1.800 2.10 15-25
______________________________________
An XPS depth profile for sample 4 (Ar/H.sub.2 (sccm)=25/50, pressure=0.60)
is illustrated in FIG. 7 which shows the oxygen content varying on average
between about 25 and 30% (atomic) through the depth of the film.
FIG. 8 illustrates the roughness of the aluminum-containing film samples.
As FIG. 8 illustrates, the higher the amount of hydrogen gas delivered to
the sputter deposition chamber (i.e., the lower the Ar/H.sub.2
ratio--x-axis), the smoother the aluminum-containing film (i.e., lower
roughness--y-axis).
FIG. 9 illustrates a thin film transistor 120 utilizing a gate electrode
and source/drain electrodes which may be formed from an
aluminum-containing film produced by a method of the present invention.
The thin film transistor 120 comprises a substrate 122 having an
aluminum-containing gate electrode 124 thereon which may be produced by a
method of the present invention. The aluminum-containing gate electrode
124 is covered by an insulating layer 126. A channel 128 is formed on the
insulating layer 126 over the aluminum-containing gate electrode 124 with
an etch stop 130 and contact 132 formed atop the channel 128. An
aluminum-containing source/drain electrode 134 which may be produced by a
method of the present invention is formed atop the contact 132 and the
insulating layer 126, and contacts a picture cell electrode 136. The
aluminum-containing source/drain electrode 134 is covered and the picture
cell electrode 136 is partially covered by a passivation layer 138.
FIG. 10 is a schematic of a standard active matrix liquid crystal display
layout 150 utilizing column buses 152 and row buses 154 formed from an
aluminum-containing film produced by a method of the present invention.
The column buses 152 and row buses 154 are in electrical communication
with pixel areas 156 (known in the art) to form the active matrix liquid
crystal display layout 150.
Having thus described in detail preferred embodiments of the present
invention, it is to be understood that the invention defined by the
appended claims is not to be limited by particular details set forth in
the above description, as many apparent variations are possible without
departing from the spirit or scope thereof.
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